{-# LANGUAGE MagicHash #-}
{-# LANGUAGE RecordWildCards #-}
{-# LANGUAGE TemplateHaskell #-}
{-# LANGUAGE TupleSections #-}
{-# LANGUAGE ViewPatterns #-}
module Clash.Netlist where
import Control.Exception (throw)
import Control.Lens ((.=),(^.),_1,_3)
import qualified Control.Lens as Lens
import Control.Monad.IO.Class (liftIO)
import Control.Monad.State.Strict (runStateT)
import Data.Binary.IEEE754 (floatToWord, doubleToWord)
import Data.Char (ord)
import Data.Either (lefts,partitionEithers)
import Data.HashMap.Lazy (HashMap)
import qualified Data.HashMap.Lazy as HashMap
import Data.List (elemIndex)
import Data.Maybe (catMaybes)
import Data.Primitive.ByteArray (ByteArray (..))
import qualified Data.Text.Lazy as Text
import qualified Data.Vector.Primitive as PV
import GHC.Integer.GMP.Internals (Integer (..), BigNat (..))
import System.FilePath ((</>), (<.>))
import Text.Read (readMaybe)
import Unbound.Generics.LocallyNameless
(Embed (..), runFreshMT, unbind, unembed, unrebind)
import Outputable (ppr, showSDocUnsafe)
import SrcLoc (SrcSpan,isGoodSrcSpan,noSrcSpan)
import Clash.Annotations.TopEntity (TopEntity (..))
import Clash.Core.DataCon (DataCon (..))
import Clash.Core.FreeVars (typeFreeVars)
import Clash.Core.Literal (Literal (..))
import Clash.Core.Name (Name(..), name2String)
import Clash.Core.Pretty (showDoc)
import Clash.Core.Term
(Alt, Pat (..), Term (..), TmName, TmOccName)
import qualified Clash.Core.Term as Core
import Clash.Core.Type (Type (..), splitFunTys)
import Clash.Core.TyCon
(TyCon, TyConOccName)
import Clash.Core.Util (collectArgs, termType)
import Clash.Core.Var (Id, Var (..))
import Clash.Driver.Types
(BindingMap, ClashException (..))
import Clash.Netlist.BlackBox
import Clash.Netlist.BlackBox.Types (BlackBoxTemplate)
import Clash.Netlist.Id
import Clash.Netlist.Types as HW
import Clash.Netlist.Util
import Clash.Primitives.Types as P
import Clash.Util
genNetlist :: BindingMap
-> [(TmName,Type,Maybe TopEntity,Maybe TmName)]
-> PrimMap BlackBoxTemplate
-> HashMap TyConOccName TyCon
-> (HashMap TyConOccName TyCon -> Bool -> Type -> Maybe (Either String HWType))
-> [(String,FilePath)]
-> Int
-> (IdType -> Identifier -> Identifier)
-> (IdType -> Identifier -> Identifier -> Identifier)
-> [Identifier]
-> FilePath
-> TmOccName
-> IO ([(SrcSpan,Component)],[(String,FilePath)],[Identifier])
genNetlist globals tops primMap tcm typeTrans dfiles iw mkId extId seen env topEntity = do
(_,s) <- runNetlistMonad globals (mkTopEntityMap tops) primMap tcm typeTrans
dfiles iw mkId extId seen env $ genComponent topEntity
return (HashMap.elems $ _components s, _dataFiles s, _seenComps s)
where
mkTopEntityMap
:: [(TmName,Type,Maybe TopEntity,Maybe TmName)]
-> HashMap TmOccName (Type, Maybe TopEntity)
mkTopEntityMap = HashMap.fromList . map (\(a,b,c,_) -> (nameOcc a,(b,c)))
runNetlistMonad :: BindingMap
-> HashMap TmOccName (Type, Maybe TopEntity)
-> PrimMap BlackBoxTemplate
-> HashMap TyConOccName TyCon
-> (HashMap TyConOccName TyCon -> Bool -> Type -> Maybe (Either String HWType))
-> [(String,FilePath)]
-> Int
-> (IdType -> Identifier -> Identifier)
-> (IdType -> Identifier -> Identifier -> Identifier)
-> [Identifier]
-> FilePath
-> NetlistMonad a
-> IO (a, NetlistState)
runNetlistMonad s tops p tcm typeTrans dfiles iw mkId extId seenIds_ env
= runFreshMT
. flip runStateT s'
. runNetlist
where
s' = NetlistState s 0 HashMap.empty p typeTrans tcm (Text.empty,noSrcSpan) dfiles iw mkId extId [] seenIds' names tops env 0
(seenIds',names) = genNames mkId seenIds_ HashMap.empty (HashMap.elems (HashMap.map (^. _1) s))
genNames :: (IdType -> Identifier -> Identifier)
-> [Identifier]
-> HashMap TmOccName Identifier
-> [TmName]
-> ([Identifier], HashMap TmOccName Identifier)
genNames mkId = go
where
go s m [] = (s,m)
go s m (nm:nms) = let nm' = genComponentName s mkId nm
s' = nm':s
m' = HashMap.insert (nameOcc nm) nm' m
in go s' m' nms
genComponent
:: TmOccName
-> NetlistMonad (SrcSpan,Component)
genComponent compName = do
compExprM <- fmap (HashMap.lookup compName) $ Lens.use bindings
case compExprM of
Nothing -> do
(_,sp) <- Lens.use curCompNm
throw (ClashException sp ($(curLoc) ++ "No normalized expression found for: " ++ show compName) Nothing)
Just (_,_,_,_,expr_) -> do
makeCached compName components $ genComponentT compName expr_
genComponentT
:: TmOccName
-> Term
-> NetlistMonad (SrcSpan,Component)
genComponentT compName componentExpr = do
varCount .= 0
componentName1 <- (HashMap.! compName) <$> Lens.use componentNames
topEntMM <- fmap snd . HashMap.lookup compName <$> Lens.use topEntityAnns
let componentName2 = maybe componentName1
(maybe componentName1 (Text.pack . t_name))
topEntMM
sp <- ((^. _3) . (HashMap.! compName)) <$> Lens.use bindings
curCompNm .= (componentName2,sp)
tcm <- Lens.use tcCache
seenIds .= []
(compInps,argWrappers,compOutps,resUnwrappers,binders,result) <- do
normalizedM <- splitNormalized tcm componentExpr
case normalizedM of
Right normalized -> mkUniqueNormalized topEntMM normalized
Left err -> throw (ClashException sp err Nothing)
netDecls <- fmap catMaybes . mapM mkNetDecl $ filter ((/= result) . varName . fst) binders
decls <- concat <$> mapM (uncurry mkDeclarations . second unembed) binders
resDecl <- mkNetDecl . head $ filter ((==result) . varName . fst) binders
case resDecl of
Just (NetDecl' _ rw _ _) -> do
let (compOutps',resUnwrappers') = case compOutps of
[oport] -> ([(rw,oport)],resUnwrappers)
_ -> let NetDecl n res resTy = head resUnwrappers
in (map (Wire,) compOutps
,NetDecl' n rw res (Right resTy):tail resUnwrappers
)
component = Component componentName2 compInps compOutps'
(netDecls ++ argWrappers ++ decls ++ resUnwrappers')
return (sp,component)
_ -> do
let component = Component componentName2 compInps [] []
return (sp, component)
mkNetDecl :: (Id, Embed Term) -> NetlistMonad (Maybe Declaration)
mkNetDecl (id_,tm) = do
hwTy <- unsafeCoreTypeToHWTypeM $(curLoc) (unembed (varType id_))
wr <- wireOrReg (unembed tm)
if isVoid hwTy
then return Nothing
else return . Just $ NetDecl' (addSrcNote (nameLoc nm))
wr
(Text.pack (name2String nm))
(Right hwTy)
where
nm = varName id_
wireOrReg :: Term -> NetlistMonad WireOrReg
wireOrReg (Case _ _ (_:_:_)) = return Reg
wireOrReg (collectArgs -> (Prim nm' _,_)) = do
bbM <- HashMap.lookup nm' <$> Lens.use primitives
case bbM of
Just (BlackBox {..}) | outputReg -> return Reg
_ -> return Wire
wireOrReg _ = return Wire
addSrcNote loc = if isGoodSrcSpan loc
then Just (Text.pack (showSDocUnsafe (ppr loc)))
else Nothing
mkDeclarations
:: Id
-> Term
-> NetlistMonad [Declaration]
mkDeclarations bndr e = do
hty <- unsafeCoreTypeToHWTypeM $(curLoc) (unembed (varType bndr))
case hty of
Void {} -> return []
_ -> mkDeclarations' bndr e
mkDeclarations'
:: Id
-> Term
-> NetlistMonad [Declaration]
mkDeclarations' bndr (Var _ v) = mkFunApp bndr v []
mkDeclarations' _ e@(Case _ _ []) = do
(_,sp) <- Lens.use curCompNm
throw (ClashException sp ($(curLoc) ++ "Not in normal form: Case-decompositions with an empty list of alternatives not supported:\n\n" ++ showDoc e) Nothing)
mkDeclarations' bndr (Case scrut altTy alts@(_:_:_)) =
mkSelection bndr scrut altTy alts
mkDeclarations' bndr app =
let (appF,(args,tyArgs)) = second partitionEithers $ collectArgs app
in case appF of
Var _ f
| null tyArgs -> mkFunApp bndr f args
| otherwise -> do
(_,sp) <- Lens.use curCompNm
throw (ClashException sp ($(curLoc) ++ "Not in normal form: Var-application with Type arguments:\n\n" ++ showDoc app) Nothing)
_ -> do
(exprApp,declsApp) <- mkExpr False (Right bndr) (unembed $ varType bndr) app
let dstId = Text.pack . name2String $ varName bndr
assn = case exprApp of
Identifier _ Nothing -> []
_ -> [Assignment dstId exprApp]
return (declsApp ++ assn)
mkSelection
:: Id
-> Term
-> Type
-> [Alt]
-> NetlistMonad [Declaration]
mkSelection bndr scrut altTy alts = do
alts' <- reorderPats <$> mapM unbind alts
tcm <- Lens.use tcCache
scrutTy <- termType tcm scrut
scrutHTy <- unsafeCoreTypeToHWTypeM $(curLoc) scrutTy
altHTy <- unsafeCoreTypeToHWTypeM $(curLoc) altTy
scrutId <- extendIdentifier Extended
(Text.pack (name2String (varName bndr)))
(Text.pack "_selection")
(_,sp) <- Lens.use curCompNm
(scrutExpr,scrutDecls) <- first (mkScrutExpr sp scrutHTy (fst (head alts'))) <$> mkExpr True (Left scrutId) scrutTy scrut
(exprs,altsDecls) <- (second concat . unzip) <$> mapM (mkCondExpr scrutHTy) alts'
let dstId = Text.pack . name2String $ varName bndr
return $! scrutDecls ++ altsDecls ++ [CondAssignment dstId altHTy scrutExpr scrutHTy exprs]
where
mkCondExpr :: HWType -> (Pat,Term) -> NetlistMonad ((Maybe HW.Literal,Expr),[Declaration])
mkCondExpr scrutHTy (pat,alt) = do
altId <- extendIdentifier Extended
(Text.pack (name2String (varName bndr)))
(Text.pack "_sel_alt")
(altExpr,altDecls) <- mkExpr False (Left altId) altTy alt
(,altDecls) <$> case pat of
DefaultPat -> return (Nothing,altExpr)
DataPat (Embed dc) _ -> return (Just (dcToLiteral scrutHTy (dcTag dc)),altExpr)
LitPat (Embed (IntegerLiteral i)) -> return (Just (NumLit i),altExpr)
LitPat (Embed (IntLiteral i)) -> return (Just (NumLit i), altExpr)
LitPat (Embed (WordLiteral w)) -> return (Just (NumLit w), altExpr)
LitPat (Embed (CharLiteral c)) -> return (Just (NumLit . toInteger $ ord c), altExpr)
LitPat (Embed (Int64Literal i)) -> return (Just (NumLit i), altExpr)
LitPat (Embed (Word64Literal w)) -> return (Just (NumLit w), altExpr)
LitPat (Embed (NaturalLiteral n)) -> return (Just (NumLit n), altExpr)
_ -> do
(_,sp) <- Lens.use curCompNm
throw (ClashException sp ($(curLoc) ++ "Not an integer literal in LitPat:\n\n" ++ showDoc pat) Nothing)
mkScrutExpr :: SrcSpan -> HWType -> Pat -> Expr -> Expr
mkScrutExpr sp scrutHTy pat scrutE = case pat of
DataPat (Embed dc) _ -> let modifier = Just (DC (scrutHTy,dcTag dc - 1))
in case scrutE of
Identifier scrutId Nothing -> Identifier scrutId modifier
_ -> throw (ClashException sp ($(curLoc) ++ "Not in normal form: Not a variable reference or primitive as subject of a case-statement:\n\n" ++ show scrutE) Nothing)
_ -> scrutE
reorderPats :: [(Pat,Term)] -> [(Pat,Term)]
reorderPats ((DefaultPat,e):alts') = alts' ++ [(DefaultPat,e)]
reorderPats alts' = alts'
mkFunApp
:: Id
-> TmName
-> [Term]
-> NetlistMonad [Declaration]
mkFunApp dst fun args = do
topAnns <- Lens.use topEntityAnns
tcm <- Lens.use tcCache
case HashMap.lookup (nameOcc fun) topAnns of
Just (ty,annM)
| let (fArgTys,fResTy) = splitFunTys tcm ty
, length fArgTys == length args
-> do
let dstId = Text.pack . name2String $ varName dst
argHWTys <- mapM (unsafeCoreTypeToHWTypeM $(curLoc)) fArgTys
let argsBundled = zip argHWTys (zip args fArgTys)
argsFiltered = filter (not . isVoid . fst) argsBundled
argsFiltered' = map snd argsFiltered
hWTysFiltered = filter (not . isVoid) argHWTys
(argExprs,argDecls) <- second concat . unzip <$>
mapM (\(e,t) -> mkExpr False (Left dstId) t e)
argsFiltered'
dstHWty <- unsafeCoreTypeToHWTypeM $(curLoc) fResTy
env <- Lens.use hdlDir
manFile <- case annM of
Just ann -> return (env </> t_name ann </> t_name ann <.> "manifest")
Nothing -> do
mkId <- Lens.use mkIdentifierFn
let topName = genComponentName [] mkId fun
return (env </> (Text.unpack topName) <.> "manifest")
Just man <- readMaybe <$> liftIO (readFile manFile)
instDecls <- mkTopUnWrapper fun annM man (dstId,dstHWty)
(zip argExprs hWTysFiltered)
return (argDecls ++ instDecls)
| otherwise -> error $ $(curLoc) ++ "under-applied TopEntity"
_ -> do
normalized <- Lens.use bindings
case HashMap.lookup (nameOcc fun) normalized of
Just _ -> do
(_,Component compName compInps [snd -> compOutp] _) <- preserveVarEnv $ genComponent (nameOcc fun)
if length args == length compInps
then do
argTys <- mapM (termType tcm) args
argHWTys <- mapM coreTypeToHWTypeM argTys
let argsBundled = zip argHWTys (zip args argTys)
argsFiltered = filter (maybe True (not . isVoid) . fst) argsBundled
argsFiltered' = map snd argsFiltered
tysFiltered = map snd argsFiltered'
let dstId = Text.pack . name2String $ varName dst
(argExprs,argDecls) <- fmap (second concat . unzip) $! mapM (\(e,t) -> mkExpr False (Left dstId) t e) argsFiltered'
(argExprs',argDecls') <- (second concat . unzip) <$> mapM (toSimpleVar dst) (zip argExprs tysFiltered)
let inpAssigns = zipWith (\(i,t) e -> (Identifier i Nothing,In,t,e)) compInps argExprs'
outpAssign = (Identifier (fst compOutp) Nothing,Out,snd compOutp,Identifier dstId Nothing)
instLabel <- extendIdentifier Basic compName (Text.pack "_" `Text.append` dstId)
let instDecl = InstDecl Nothing compName instLabel (outpAssign:inpAssigns)
return (argDecls ++ argDecls' ++ [instDecl])
else error $ $(curLoc) ++ "under-applied normalized function"
Nothing -> case args of
[] -> do
let dstId = Text.pack . name2String $ varName dst
return [Assignment dstId (Identifier (Text.pack $ name2String fun) Nothing)]
_ -> error $ $(curLoc) ++ "Unknown function: " ++ showDoc fun
toSimpleVar :: Id
-> (Expr,Type)
-> NetlistMonad (Expr,[Declaration])
toSimpleVar _ (e@(Identifier _ _),_) = return (e,[])
toSimpleVar dst (e,ty) = do
argNm <- extendIdentifier Extended
(Text.pack (name2String (varName dst)))
(Text.pack "_fun_arg")
argNm' <- mkUniqueIdentifier Extended argNm
hTy <- unsafeCoreTypeToHWTypeM $(curLoc) ty
let argDecl = NetDecl Nothing argNm' hTy
argAssn = Assignment argNm' e
return (Identifier argNm' Nothing,[argDecl,argAssn])
mkExpr :: Bool
-> (Either Identifier Id)
-> Type
-> Term
-> NetlistMonad (Expr,[Declaration])
mkExpr _ _ _ (Core.Literal l) = do
iw <- Lens.use intWidth
case l of
IntegerLiteral i -> return (HW.Literal (Just (Signed iw,iw)) $ NumLit i, [])
IntLiteral i -> return (HW.Literal (Just (Signed iw,iw)) $ NumLit i, [])
WordLiteral w -> return (HW.Literal (Just (Unsigned iw,iw)) $ NumLit w, [])
Int64Literal i -> return (HW.Literal (Just (Signed 64,64)) $ NumLit i, [])
Word64Literal w -> return (HW.Literal (Just (Unsigned 64,64)) $ NumLit w, [])
CharLiteral c -> return (HW.Literal (Just (Unsigned 21,21)) . NumLit . toInteger $ ord c, [])
FloatLiteral r -> let f = fromRational r :: Float
i = toInteger (floatToWord f)
in return (HW.Literal (Just (BitVector 32,32)) (NumLit i), [])
DoubleLiteral r -> let d = fromRational r :: Double
i = toInteger (doubleToWord d)
in return (HW.Literal (Just (BitVector 64,64)) (NumLit i), [])
NaturalLiteral n -> return (HW.Literal (Just (Unsigned iw,iw)) $ NumLit n, [])
ByteArrayLiteral (PV.Vector _ _ (ByteArray ba)) -> return (HW.Literal Nothing (NumLit (Jp# (BN# ba))),[])
_ -> error $ $(curLoc) ++ "not an integer or char literal"
mkExpr bbEasD bndr ty app = do
let (appF,args) = collectArgs app
tmArgs = lefts args
hwTy <- unsafeCoreTypeToHWTypeM $(curLoc) ty
(_,sp) <- Lens.use curCompNm
case appF of
Data dc -> mkDcApplication hwTy bndr dc tmArgs
Prim nm _ -> mkPrimitive False bbEasD bndr nm args ty
Var _ f
| null tmArgs -> return (Identifier (Text.pack $ name2String f) Nothing,[])
| otherwise ->
throw (ClashException sp ($(curLoc) ++ "Not in normal form: top-level binder in argument position:\n\n" ++ showDoc app) Nothing)
Case scrut ty' [alt] -> mkProjection bbEasD bndr scrut ty' alt
_ -> throw (ClashException sp ($(curLoc) ++ "Not in normal form: application of a Let/Lam/Case:\n\n" ++ showDoc app) Nothing)
mkProjection
:: Bool
-> Either Identifier Id
-> Term
-> Type
-> Alt
-> NetlistMonad (Expr, [Declaration])
mkProjection mkDec bndr scrut altTy alt = do
tcm <- Lens.use tcCache
scrutTy <- termType tcm scrut
let e = Case scrut scrutTy [alt]
(pat,v) <- unbind alt
(_,sp) <- Lens.use curCompNm
varTm <- case v of
(Var _ n) -> return n
_ -> throw (ClashException sp ($(curLoc) ++
"Not in normal form: RHS of case-projection is not a variable:\n\n"
++ showDoc e) Nothing)
sHwTy <- unsafeCoreTypeToHWTypeM $(curLoc) scrutTy
vHwTy <- unsafeCoreTypeToHWTypeM $(curLoc) altTy
(selId,modM,decls) <- do
scrutNm <- either return
(\b -> extendIdentifier Extended
(Text.pack (name2String (varName b)))
(Text.pack ("_projection")))
bndr
(scrutExpr,newDecls) <- mkExpr False (Left scrutNm) scrutTy scrut
case scrutExpr of
Identifier newId modM -> return (newId,modM,newDecls)
_ -> do
scrutNm' <- mkUniqueIdentifier Extended scrutNm
let scrutDecl = NetDecl Nothing scrutNm' sHwTy
scrutAssn = Assignment scrutNm' scrutExpr
return (scrutNm',Nothing,newDecls ++ [scrutDecl,scrutAssn])
let altVarId = Text.pack $ name2String varTm
modifier <- case pat of
DataPat (Embed dc) ids -> do
let (exts,tms) = unrebind ids
tmsTys = map (unembed . varType) tms
tmsFVs = concatMap (Lens.toListOf typeFreeVars) tmsTys
extNms = map (nameOcc.varName) exts
tms' = if any (`elem` tmsFVs) extNms
then throw (ClashException sp ($(curLoc) ++ "Not in normal form: Pattern binds existential variables:\n\n" ++ showDoc e) Nothing)
else tms
argHWTys <- mapM coreTypeToHWTypeM tmsTys
let tmsBundled = zip argHWTys tms'
tmsFiltered = filter (maybe False (not . isVoid) . fst) tmsBundled
tmsFiltered' = map snd tmsFiltered
case elemIndex (Id varTm (Embed altTy)) tmsFiltered' of
Nothing -> pure Nothing
Just fI
| sHwTy /= vHwTy -> pure $ nestModifier modM (Just (Indexed (sHwTy,dcTag dc - 1,fI)))
| otherwise -> pure $ nestModifier modM (Just (DC (Void Nothing,0)))
_ -> throw (ClashException sp ($(curLoc) ++ "Not in normal form: Unexpected pattern in case-projection:\n\n" ++ showDoc e) Nothing)
let extractExpr = Identifier (maybe altVarId (const selId) modifier) modifier
case bndr of
Left scrutNm | mkDec -> do
scrutNm' <- mkUniqueIdentifier Extended scrutNm
let scrutDecl = NetDecl Nothing scrutNm' vHwTy
scrutAssn = Assignment scrutNm' extractExpr
return (Identifier scrutNm' Nothing,scrutDecl:scrutAssn:decls)
_ -> return (extractExpr,decls)
where
nestModifier Nothing m = m
nestModifier m Nothing = m
nestModifier (Just m1) (Just m2) = Just (Nested m1 m2)
mkDcApplication :: HWType
-> (Either Identifier Id)
-> DataCon
-> [Term]
-> NetlistMonad (Expr,[Declaration])
mkDcApplication dstHType bndr dc args = do
let dcNm = name2String (dcName dc)
tcm <- Lens.use tcCache
argTys <- mapM (termType tcm) args
argNm <- either return (\b -> extendIdentifier Extended (Text.pack (name2String (varName b))) (Text.pack "_dc_arg")) bndr
argHWTys <- mapM coreTypeToHWTypeM argTys
let argsBundled = zip argHWTys (zip args argTys)
argsFiltered = filter (maybe True (not . isVoid) . fst) argsBundled
argsFiltered' = map snd argsFiltered
hWTysFiltered = filter (maybe True (not . isVoid)) argHWTys
(argExprs,argDecls) <- fmap (second concat . unzip) $! mapM (\(e,t) -> mkExpr False (Left argNm) t e) argsFiltered'
fmap (,argDecls) $! case (hWTysFiltered,argExprs) of
([Just argHwTy],[argExpr]) | argHwTy == dstHType ->
return (HW.DataCon dstHType (DC (Void Nothing,-1)) [argExpr])
_ -> case dstHType of
SP _ dcArgPairs -> do
let dcI = dcTag dc - 1
dcArgs = snd $ indexNote ($(curLoc) ++ "No DC with tag: " ++ show dcI) dcArgPairs dcI
case compare (length dcArgs) (length argExprs) of
EQ -> return (HW.DataCon dstHType (DC (dstHType,dcI)) argExprs)
LT -> error $ $(curLoc) ++ "Over-applied constructor"
GT -> error $ $(curLoc) ++ "Under-applied constructor"
Product _ dcArgs ->
case compare (length dcArgs) (length argExprs) of
EQ -> return (HW.DataCon dstHType (DC (dstHType,0)) argExprs)
LT -> error $ $(curLoc) ++ "Over-applied constructor"
GT -> error $ $(curLoc) ++ "Under-applied constructor"
Sum _ _ ->
return (HW.DataCon dstHType (DC (dstHType,dcTag dc - 1)) [])
Bool ->
let dc' = case dcTag dc of
1 -> HW.Literal Nothing (BoolLit False)
2 -> HW.Literal Nothing (BoolLit True)
tg -> error $ $(curLoc) ++ "unknown bool literal: " ++ showDoc dc ++ "(tag: " ++ show tg ++ ")"
in return dc'
Vector 0 _ -> return (HW.DataCon dstHType VecAppend [])
Vector 1 _ -> case argExprs of
[e] -> return (HW.DataCon dstHType VecAppend [e])
_ -> error $ $(curLoc) ++ "Unexpected number of arguments for `Cons`: " ++ showDoc args
Vector _ _ -> case argExprs of
[e1,e2] -> return (HW.DataCon dstHType VecAppend [e1,e2])
_ -> error $ $(curLoc) ++ "Unexpected number of arguments for `Cons`: " ++ showDoc args
RTree 0 _ -> case argExprs of
[e] -> return (HW.DataCon dstHType RTreeAppend [e])
_ -> error $ $(curLoc) ++ "Unexpected number of arguments for `LR`: " ++ showDoc args
RTree _ _ -> case argExprs of
[e1,e2] -> return (HW.DataCon dstHType RTreeAppend [e1,e2])
_ -> error $ $(curLoc) ++ "Unexpected number of arguments for `BR`: " ++ showDoc args
String ->
let dc' = case dcTag dc of
1 -> HW.Literal Nothing (StringLit "")
_ -> error $ $(curLoc) ++ "mkDcApplication undefined for: " ++ show (dstHType,dc,dcTag dc,args,argHWTys)
in return dc'
Void {} -> return (Identifier (Text.pack "__VOID__") Nothing)
Signed _
| dcNm == "GHC.Integer.Type.S#"
-> pure (head argExprs)
| dcNm == "GHC.Integer.Type.Jp#"
-> pure (head argExprs)
| dcNm == "GHC.Integer.Type.Jn#"
, HW.Literal Nothing (NumLit i) <- head argExprs
-> pure (HW.Literal Nothing (NumLit (negate i)))
Unsigned _
| dcNm == "GHC.Natural.NatS#"
-> pure (head argExprs)
| dcNm == "GHC.Natural.NatJ#"
-> pure (head argExprs)
_ -> error $ $(curLoc) ++ "mkDcApplication undefined for: " ++ show (dstHType,dc,args,argHWTys)